House structure and heating system therefor



Juy w, E951 F. w. GAY

HoUsE STRUCTURE AND HEATING SYSTEM THEREEOE 2 Sheets-Sheet l Filed Aug. 25, 1948 F. W. GAY HOUSE STRUCTURE AND HEATING SYSTEM THEREFQR .I uly 10, 1951 2 snets-sneet 2 AFiled Aug. 25, 1948 WWI/WWW Mans/.wif

Patented July 10, 1951 HOUSE STRUCTURE AND HEATING SYSTEM THEREFOR Frazer W. Gay, Metuchen, N.

Application August Z5, 1948, Serial No. 46,105

Claims. (Cl. 237-50) This invention relates to a novel house structure and heating system therefor, including means to conserve generated heat which is employed for interior heating by ground storage of the generaltype disclosed in my co-pending application Ser. No. 46,104; the instant system including means to supplement the generated heat by heat derived from solar radiation.

The invention has reference, more particularly, to a novel house structure provided with means to greatly increase the availability of solar radiation for interior heating thereof, so as to reduce the total amount of heat energy demand upon any type of heat generator employed as a main source of heat, and especially upon electrically supplied heat produced by the method known to the art as the Hall heating method.

In the Hall method, electric heaters are provided to heat water stored in tanks. These electric heaters are connected to electric utility company lines, and are assumed to take power therefrom over an approximate period of eight hours comprehended by light load night hours, and, during such period, is assumed to utilize about three times the normal house heat demand; this is not the case, however, since the demand for house heat is much greater than normal during said eight hour night period, and consequently the Hall method is found to require an electric power consumption about double that of an ordinary direct electric heating system which only generates and delivers heat when and as required. In theory, under the Hall method, the heat storage tanks should be able to store about one-half of the total heat produced per day with a 60 F .temperature change, but, in practice, said tanks are sized to provide about twenty-five per cent greater storage capacity, so that some excess of stored heat is available to carry through a particularly cold day.

Having the above in view, it is an object of this invention to provide a house structure so constructed that its habitable interior is surrounded by spaced inner and outer insulating walls which define an enveloping space through which air may be circulated, said envelope space including storage therein as an available auxiliary heat supply supplementary to the generated heat, so that the capacity of the interior heat generator employed, or of an electric heating means and associated storage tanks when utilized, may be substantially reduced, e. g. as much as forty per cent, and the total expenditure of electric energy required for adequate interior heating is, in fact, reduced even more in the fall and especially in the spring of the year, since a substantial part of the required heat, at such times, is supplied by solar energy.

Other objects of this invention, not at this time more particularly enumerated, will be understood from the following detailed description of the same.

An illustrative embodiment of the novel house structure according to this invention is shown 1n the accompanying drawings, in which:

Fig. 1 is a transverse vertical sectional view of the house structure, taken on line I--I in Fig. 2; Fig. 2 is a horizontal sectional view of the same, taken on line 2--2 in Fig. 1; and Fig. 3 is a fragmentary cross sectional view, taken on line 3 3 in Fig. 1, but drawn on a somewhat enlarged scale.

Similar characters of reference are employed in the hereinabove described views, to indicate corresponding parts.

Referring to the drawings, the reference charn I acter I indicates the wall studs of the building portions contiguous to the earth so that heat may structure, and 2 the beams which support the upper oor ceiling and roof. Said studs and beams are preferably of channel form produced from steel, aluminum or other suitable'metallic ma-.

terial. 'Ihe webs of said studs and beams are punched to provide spaced openings 3 extending along their neutral axes throughout the lengths thereof. The studs I are supported on footings 4 which are countersunk in the earth below ground level. Supported by the studs and beams I and 2 is an outer wall 5 which completely surrounds the sides and top of the building above ground level. Said outer wall 5 is formed from a materia-l having desirable heat insulating characteristics, such e. g. as Vermiculite plaster or similar material. Said vermiculite plaster is applied to metal or other lath (not shown) which is afxed to the outer flanges of the studs I and beams 2; such application may be made by hand or gunned into place. An inner Wall 6 of like material and construction is mounted on the inner ilanges of the studs I and beams 2. The walls 5 and 6, as spaced by the studs and beams, define an intermediate air passage envelope which surrounds the building interior.

The side Wall structure is extended downwardly below ground level or grade so that the outer side walls 5 extend below frost line; usually for a distance of at least two feet. Within the side wall structure as thus extended the earth is excavated -to ysuitable depth. Contiguous to the subterranean extension of the side walls 5 is arranged a body H of concrete or cement of high thermal conductive characteristics, which extends downward to the floor .of the excavated interior. Said body Il is made of suitable thickness, and serves in lieu of a foundation. The concrete or cement body Il contributesto vtransfer of heat from the earth to the air circulating within the wall structure envelope.

A concrete base floor 'l of suitable thickness is laid directly upon the earth within the building interior. Laid on this floor -to extend between .studs ll at opposite sides .of the building structure, are sleepers 8. These sleepers 8 may be .of .either channel or I-beam form, and are preferably made of steel. Supported by said sleepers A8 is an interior .flooring 9, which preferably compises a two inch layer of vermiculite conc1ete,fover which -is laid a surfacing floor Hl, which may be of standard concrete, asphalt, tile ,or other material adapted to furnish suitable wearing surface. The intervening space between the base floor l and interior ooring e extends .between said opposite sides of the building structure Vso as to provide a bottom air iiow .course A in communication with the air circulating envelope formed in the side and top wall structures. The webs of said sleepers 8 are punched to provide spaced openings 3 extending along the same, similarly -as is done with respect to the studs l and beams 2, whereby communication is established between the parallel air flow `channels intermediate said studs, beams `and sleepers.

VThat part of the air circulating envelope provided by the side wall structure is subdivided by imperforate studs I2 preferably located within the front `and back sections of said side wall structure, whereby to form, in one half of the side wall structure, a rising air flow `course B, and, in the opposite half thereof .a descending air fiow course C; communication between the rising and descending courses being established through .the upper horizontal .part of the air circ'lilating lenveiope which is dened by the .beams 2, and which provides a transfer air ow course Countersunk in the base floor 'i below onehalf of the building to extend between the front and back of the latter as shown, is a duct I3. This duct is subdivided along its length by a partition i4, whereby to provide an air receiving chamber l5, with which the descending air flow course C communicates through one end of the bottom air flow course A, and an air discharging chamber I6, which communicates Vwith the rising airflow course B through the opposite end of said bottom air ow course A. Mounted in the partition -ld is a reversible -motor driven air impeller fan I'i, which moves the air from the receiving chamber 1.5 to .the discharging chamber 16, or vice versa at will.

.In an illustrative embodiment of house structure according to the instant invention, the same is provided with a gabled roof structure supported byrafters4 I8. The rafters at the south side of the roof structure are provided with a 4 roofing I9 of sheet metal, preferably aluminumj the external surface of which is painted a dark color so as to reduce heat reflection and increase heat transmission therethrough. Aixed to the underside of the rafters I8 of said southern side of the roof structure is an internal wall 20 of insulating material, such e. g. as vermiculite. The space between the roofing t9 and wall 20 provides a `roof air ow course E. Insulating walls 2l rising between the top exterior wall 5 and the roofing define an intercommunicating aii` flow passage F between the transfer air iow `course `D andthe roof air flow course E. Air

delivery communication between the transfer air iiowcourse D and the roof air flow course E by way of said air ow course E' may be opened and closed by a vmanipulable damper 22, which when `.opened to flow of air to the course E, will close 01T flow of air toward the southern side of the building 'through that part of the transfer air ow course D 'beyond said damper. Air discharge communication between the roof air now course E back to the transfer air now course D, .and thence to the air flow course B, is provided .by a discharge port 23, adapted to 'be opened and closed 'by a manipulatable control damper`24.

Suitably -located within the lowerstorey of the building is a .suitabie heat generating means. Hot .air is delivered from the heat generating means into passage space G between the door 25 of the upper storey and the ceiling 26 of the lower storey of the building, being distributed thence through hollow partitions 2i which define Vthe rooms of each storey, Vfor discharge, through registers .or other outlets 21', into said rooms.

A Vpreferred neat generating means, as shown, comprises water storage tanks 23 which are heated by .suitable electrical heaters 29. Said tanks 28 are suitably mounted within an enclosure or hot box 3i). Air is admitted into the bottom of said Venclosure or hot .box Bil, through gravity closed louvres 3| provided in an external wa-ll of the latter. The upper end of the enclosure or hot box 3i) communicates with the hot air delivery passage G, and circulation -of air through the house interior `and enclosure or hot vbox 3S is preferably effected by means of a motor driven impeller fan 32 mounted within the upper discharge end of said enclosure or'hot box 39. Ifdesired, anelectrical radiator 33 may be used as `an auxiliary to the storage tanks 28, although since radiation area in the form of the tanks Y28 costs but little more than that provided by electrical radiators, it follows that, with the tanks, the water storage `'function thereof costs but little if credit is 4taken for .the radiating surface which the tanks provide.

As an adjunct to the solar energy utilizing means of the house heating system, the outer wall 5 at the southern side of vthe building is provided with transparent window structure 34 of substantial area, and preferabiy double glazed, thus permitting a considerable amount of solar rays R-R to pass lthrough the window and impinge upon the inner wall 6, `being thus conver-ted to sensible heat within .the air circulat- A ing envelope. The vsolar rays `therefore not only that solar rays R-R are cut o from the window structure 34 during the noon period in the summer season when the sun is high overhead. The extent of said overhanging extension 35 is so limited, however, as not to cut orf solar rays R--R from said window structure 34 in the winter season when the sun is low in south even during the noon period.

In cold weather, the fan I'I drives air from the discharging chamber I6 through the bottom air flow course A, thence upwardly through the rising air now course B, across the transfer air ilow course D, and downwardly through the descending air fiow course C to the receiving chamber I5. If it is extremely cold out doors, the air moving through the bottom air flow course A in contact with the earth supported base floor l picks up heat from the contiguous earth mass, since underground temperature is considerably higher than ambient temperature under cold weather conditions. Illustrative of this, extensive tests show that underground temperatures in the neighborhood of metropolitan New York city e. g. average about 50 F., and this temperature changes but little throughout the year for depths in excess of ten feet. The heat transferred to the air from the earth is dissipated as the air is circulated, through the envelope by which the building is surrounded.

From the above it will be obvious that the novel building structure provides a thin envelope of recirculating air which surrounds the building interior, a portion of which envelope is contiguous to the earth so as to promote the transfer of heat to and from the air from and to the earth upon relatively slight temperature difierential. In warm winter weather (above 30 FJ, the heat passes from the recirculatin-g air into the earth, thus increasing the normal now of heat from the interior of the building across the inner heat insulating wall E so that this increment of heat is largely stored in the underlying ground. In cold winter weather (approximating zero), the stored heat passes from the ground into the recirculating air, and thus greatly reduces the drain on the heating generator, so as to economize operation of the latter.

The heating operations in the novel building structure are substantially as follows; to maintain an interior temperature approximating '72 F Assuming the normal average outdoor temperature to approximate 30 F. (as e. g. in the metropolitan New York city area), and that the outer wall 5 of the air envelope possesses a heat conductivity approximating 1000 B. t. u. per hour per degree F., and that the inner wall $3 of said air envelope also possesses a heat conductivity approximating 1000 B. t. u. per hour per degree F.; the air Within the envelope would normally possess a mid temperature of 30 plus 72 2 0r 51 F., and the drop across the inner wall 6, from heat supplied by furnace I8, would be 21 F., i. e. the furnace I8 would be required to produce an output of approximately 21X1000 or 21,000 B. t. u. per hour. However, ii the normal earth temperature is 50 F., some heat would be stored in the ground, and the furnace IS would have a somewhat higher output. For outdoor temperatures higher than 30 F. (e. g. a maximum of 60 F.), the envelope air would normally tend to possess an average temperature of approximately 6o plus v2 r 2 or 66 F., andthe furnace would only supply 6X 1000 or 6000 B. t. u. per hour. However, the earth can be expected to store heat, transferred thereto from the envelope air, and thus to maintain an envelope air temperature of approximately 55 F., so that the furnace need only supply 17X1000 or 17,000 B. t. u. per hour. Under these circumstances, the drop across the outer wall 5 will approximate 5 F. negative, so that 5X1000 or 5000 B. t. u. will be transferred to the earth from outdoors, thus a total heat storage in the ground of 17,000 plus 5000 or 22,000 B. t. u. per hour will be accumulated. The conducting underground wall I I absorbs over 4000 B. t. u. per degree F.

At zero outdoor temperature, without considering earth storage heat, the envelope air would possess a temperature of 0 plus 'l2/2 or 36 F., and the furnace i8 would be required to supply 36X1000 or 36,000 B. t. u. If, however, 'I' is assumed to be the temperature of the envelope air, then (T2- T) X100() equals output of the furnace, and TX 1000 equals heat passing through outside wall 5 and TX l000-(72-T) X 1000 is the amount of heat desired from ground storage. If the ground is assumed to yield 4000 B. t. u. per degree F. of variation above 50 F.,then (5G-T) X400() equals available storage heat, and

TX 1000- C72-T) X 1000:(50-T) X400() and T equals approximately 451/3o F., so that ground stored heat will supply about 42/3X4000 or 18,700 B. t. u. per hour, of the 45,300 B. t. u. required, leaving but approximately 26,600 B. t. u. necessary to be supplied by the furnace i3, instead of 36,000 B. t. u. normally needed, thus normally effecting a saving in furnace capacity required of W/36,000 or about 26 per cent.

In the use of the solar heat supplied features of the invention, during cold winter weather (below 30 F.) the dampers 22 and 2li are closed to exclude circulation of air through the roof air flow course E, but in Warm sunny winter Weather (above 30 F), these dampers 22 and 215i are opened to shunt the envelope circulated air through the roof air flow course E, and under the latter conditions the air impeller fan Il is reversed, to reverse direction of circulation of air through the air envelope, so that the air Iiows upward through the air iiow course C, thence by way of the transfer air flow course D through the roof air flow course and from the latter down the air ow course B to the bottom air iiow course A. The air as thus circulated picks up heat derived from solar energy transmitted through roofing I9, and additionally from soiar energy transmitted through the window structure 3ft. The thus additionally warmed air hows into the bottom air flow course A in heat transfer contact with the earth, to which it gives up heat for storage subject to future demand. The solar energy derived heat, by reason of the reversed circulation of air through the recirculating envelope is mainly transferred to the earth underlying the southern part of the house, so that the earth which underlies the southern part of the house is warmer than that Which underlies the northern part of the house.

Since the solar energy converted into sensible heat Within the air circulating envelope can gain no Adirect iaccess .through .to the house interior by reason of the shielding inner Wall E, 'which preferably is coincident to ,the entire area of the south side Wall of the building, it is preferable that all windows opening into the house interior are reduced to a minimum, and these located in other than the south `Wall'of Ythe kbuilding. From this it follows, that, if desired, substantially the entire outer 'wall at the south side of the building 'may be made Vof solar energy transmitting character vso that a maximum amount of sensible -heat gain `derived from sol-ar energy may be rendered available for ystorage and later use.

The supplementary heat derived Yfrom 'solar energy according to this invention and transferred to the earth underlying the vbuilding 'may be assumed to raise the Vnormal underlying earth temperature approximately F. As above stated, it is assumed that the outer and inner insulating house Walls 5 and :El possess a Vthermal conductivity of i080 B. t. u. per hour `perdegree F., and that the heat conductive Wall 'l between the bottom air iiovv course A and the earth has a conductivity of approximately 5600 B. t. u. 'per hour per degree F. At Zero outdoor'temperature, without heat storage Vfor solar energy aid, the house air temperature Within the air recirculating envelope would approximate 36 F., and the house heating generator Would be required to supply 36,000 B. t. u. per hour. With the `vsolar energy heat supply considered, the air temperature within the air recirculating envelope 'may be considered as T, and TX 1000 B. t. u. per hour would pass through the outer envelope wall 5, and C72-T) l000 B. t. u. would pass through the inner envelope wall E. Under these circumstances, the stored heat from the underlying earth would supply A(S5-T) X566() B. t. u. which equals T l000(72-T) X100@ so that T is .of the order of 50 F. Consequently about `50,000 B. t. u. passing through the outer envelope wall 5 and 22,900 B. t. u. passing through the inner Wall li, with 28,0@6 B. t. u. per hour derived from earth stored heat Vas a maximum .stored heat drain. The saving effected with respect to required generated heat capacity, under my .novel system including solar energy aid, will approximate 36,060 B. t. u. (normal) less 22,000 B. t. u. or about 39 per cent.

I am Aaware that changes could be made in the above described building structure, and that different embodiments of my inventioncould be made Without departing from the scope thereof as dened in the following claims. It is A'therefore intended that all matter contained in the foregoing description or shown in the iaccompanying drawings shall be interpreted as illustrative and not in a limiting sense.

I claim:

l. A house structure comprising side and -top wall structures formed by spaced outer and rinner Walls of heat insulating character, the space between said outer and inner Walls providing, in part, an air circulating envelope surrounding the house interior, a ground floor structure cornprising a base floor of heat conductive 'character contiguous to the earth and `interior floor-ing of heat insulating material spaced above said base floor so as lto complete the air circulating envelope around the house interior, means to 'normally circulate air in one direction from the ground floor portion of said envelope through the side and top wall portions thereof back to the ground oor portion thereof, whereby Ithe air .moving :through :saidfground floor portion ofthe envelope is vin heat transfer Contact Vvvith the 'underlying earth, and Ameans to supply .solar energy .derived heat ato the air in said air circulating envelope.

2. A house structure comprising side and top wallstructures formed by spaced outer and inner walls of heat insulating character, the space between said outer and inner walls providing, in part, an air circulating envelope surrounding the house interior, a ground floor structure comprising a base floor of heat conductive character contiguous to the earth and interior flooring `of heat insulating material spaced above said base floor so as .to complete the air circulating envelope around .the house interior, `means to normally circulate air in one direction from the ground door portion ol said .envelope through the side and top wall portions thereof back to the ground floor .portion thereof, whereby `the `air moving through said ground floor portion of the envelope is -in heat transfer contact with the underlying earth, vand Kmeans tc supply solar energy derived heat to the air in said air circulating envelope, said latter means comprising .a rheat conductive roof section exposed to solar rays, an insulating wall spaced beneath said roobsection to provide a roof contiguous air vlovv course, means to conneet said roof contiguous air lot-v course in shunt communication lwith the air circulating envelope, and manipulatable means to open and close such communication.

3. A house structure comprising .side and top wall structures 'formed by spaced-outer andinner Walls of heat insulating character, the space between said outer and inner Walls providing, in part, an air circulating envelope surrounding the house interior, a ground door structure comprising a-base hoor-of heat conductive character contiguous to the earth and interior :flooring of `heat insulating material spaced above said vbase floor so as to complete the air circulating envelope around the house interior, means to normally circulate air in one direction from the ground floor portion .of said envelope through the side and top wall portions thereof back tothe ground iloor portion thereof, whereby .the air moving through said ground floor portion of the envelope is in heat transfer contact with the underlying earth, and means -to supply solar energy derived heat to the air in said air circulating envelope, said latter means comprising a heat .conductive roof section exposed to solar rays, an insulating Wall spaced beneath said roof section to provide a roof contiguous air flow course, means tovconnect said roof contiguous `air now course in shunt communication with the air circulating envelope, manipulatable means to open and close such communication, anda southerly exposed section of the envelope outer wall having a solar ray admission portion therein comprising a double glazed Window structure contiguous to which the envelope passage extends.

4. A house structure comprising side and top Wall structures formed by spaced outer and inner walls of heat insulating character, the space between said -outer and inner walls providing, in part, an air'circulating envelope surrounding the house interiona ground oor structure comprising a base iloor of l.heat conductive character `contiguous to the earth and interior flooring of heat insulating material spaced above said base floor so .as to complete the air circulating envelope around the house interior, a heat generating and supplying `means Within the house interior, means to distribute the supplied heat through the house interior, reversible means to normally circulate air in one direction from the ground floor portion of said envelope through the side and top wall portions thereof back to the ground floor portion thereof, whereby the air moving through said ground floor portion of the envelope is in heat transfer contact with the underlying earth, and means to supply solar energy derived heat to the air in said air circulating envelope when the flow direction of the circulating air withn the latter is reversed.

5. A house structure comprising side and top wall structures formed by spaced outer and inner walls of heat insulating character, the space between said outer and inner walls providing, in part, an air circulating envelope surrounding the house interior, a ground iioor structure comprising a base iioor of heat conductive character contiguous to the earth and interior flooring of heat insulating material spaced above said base floor so as to complete the air circulating envelope around the house interior, a heat generating and supplying means within the house interior, means to distribute the supplied heat through the house interior, reversible means to normally circulate air in one direction from the ground floor portion of said envelope through the side and top wall portions thereof back to the ground iioor portion thereof, whereby the air moving through said ground iioor portion of the envelope is in heat transfer contact with the underlying earth, means to supply solar energy derived heat to the air in said air circulating envelope when the flow direction of the circulating air within the latter is reversed, said latter means comprising a heat conductive roof section exposed to solar rays, an insulating wall spaced beneath said roof section to provide a roof contiguous air flow course, means to connect said roof contiguous air ow course in shunt communication with the air circulating envelope, and manipulatable means to open and close such communication.

6. A house structure comprising side and top wall structures formed by spaced outer and inner Walls of heat insulating character, the space between said outer and inner walls providing, in part, an air circulating envelope surrounding the house interior, a ground iioor structure comprising a base floor of heat conductive character contiguous to the earth and interior iiooring of heat insulating material spaced above said base iioor so as to complete the air circulating envelope around the house interior, a heat generating and supplying means within the house interior, means to distribute the supplied heat through the house interior, reversible means to normally circulate air in one direction from the ground floor portion of said envelope through the side and top wall portions thereof back to the ground floor portion thereof, whereby the air moving through said ground floor portion or" the envelope is in heat transfer contact with the underlying earth, means to supply solar energy derived heat to the air in said air circulating envelope when the flow direction of the circulating air within the latter is reversed, said latter means comprising a heat conductive roof section exposed to solar rays, an insulating wall spaced beneath said roof section to provide a roof contiguous air flow course, means to connect said roof contiguous air flow course in shunt communication With the air circulating envelope, manipulatable means to open and close such communication, .and a southerly exposed section of the envelope outer wall having a solar ray admission portion thereincomprising a double glazed window structure contiguous. to which the envelope passage extends.

7. A house structure comprising side and top wall structures formed by spaced outer and inner walls of heat insulating character, the space between said outer and inner walls providing, in part, an air circulating envelope surrounding the house interior, a ground floor structure comprising a base oor or heat conductive character contiguous to the earth and interior flooring of heat insulating material spaced above said base floor so as to complete the air circulating envelope around the house interior, aheat generating and supplying means within the house interior, means to distribute the supplied heat through the house interior, reversible means to normally circulate air in one direction from the ground floor portion of said envelope through the side and top wall portions thereof back to the groundfloor portion thereof, whereby the air moving through said ground floor portion of the envelope is in heat transfer contact Iwith the underlying earth, means to supply solar energy derived heat to the air in said air circulating envelope when the iiow direction of the circulating air within the latter is reversed, said latter means including a solar ray admission portion in the southerly exposed section of the envelope outer wall comprising a double glazed window structure ycontiguous to which the envelope passage extends.

8. A house structure comprising external side, top .and bottom wall structures having spaced outer and inner walls adapted to provide an air circulating envelope surrounding the entire interior of the house, said walls being of heat insulating character except for those areas of the outer wall contiguous to the earth which are of heat conductive character whereby to promote transfer oi heat between the contiguous earth and .air circulating in said envelope,`a heat generating means within the house interior to supply internal heat to said house interior, reversible air impulsion means to normally induce ow of air within the envelope in one direction, whereby heat from the interior heat generating means is carried to the underlying earth for storage therein, means to supply solar energy derived heat to the air in said envelope when ilow direction of the air within the latter is reversed, said latter means comprising a heat conductive roof section exposed to solar rays, an insulating wall spaced beneath said roof section to provide a roof contiguous air flow course, means to connect said roof contiguous air flow course in shunt communication with the air circulating envelope, and manipulatable meansto open and close such communication.

9. A house structure comprising external side, top and bottom wall structures having spaced outer and inner walls adapted to provide an air circulating envelope surrounding the entire interior of the house, said Iwalls being of heat insulating character except for those areas of the outer wall contiguous to the earth which are of heat conductive character whereby to promote transfer of heat between the contiguous earth and air circulating in said envelope, a heat generating means within the house interior to supply internal heat to said house interior, reversible air impulsion means to normally induce flow of air within the envelope in one direction, whereby heat from the interior heat generating means is carried to the underlying earth for storage therein, means to supply solar energy derived heat to the air in said envelope when flow direction of lil the air' Within the latter is reversed, said latter means comprising a heat conductive roof section exposed to solar' rays, an insulating Wall spaced beneath said roof section to provide a roof contiguous air iovvcourse, means toY connect said roofv contiguous air flow course in shunt communication with the* air circulating envelope, manipulatable means toopen andY close such communication, and: a southerly exposed section of the. envelope outerwall having a solar ray admission portion therein comprising a double glazed window'structure contiguous to which the enve- Iope passage extends.

10'; A house structure comprising external side, topn andi bottom wall structures having spaced outer` and inner Walls adapted; to provide an air circulating` envelope surrounding the entire interior ofthe house, saidY Walls being of heat insulatingcharacter except for those areas of' the outerwall contiguous to the earth which are of heat conductive character whereby to promote transfer' ofA heat between the contiguous earth and air circulating in said envelope, a heat gen'- eratingjmeans withinthe house interior'to supply internal heat to saidi house interior, reversible air impulsion means to normally induce flow of a-i`1Y Within the envelope in one direction, whereby heat from the interiorA heat generatingn meansv is carried to the-underlying earth for'storage therein, means to supplyD solar energy derived heatto 12 the air in said envelope when ow direction oi the air within the latter is reversed, said latter means including a solar ray admission portion in the southerly exposed section of the envelope outerwall.

FRAZER W. GAY.

REFERENCES CITED The following references are of record in the file of this patent:

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